diff options
author | André Fabian Silva Delgado <emulatorman@parabola.nu> | 2015-08-05 17:04:01 -0300 |
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committer | André Fabian Silva Delgado <emulatorman@parabola.nu> | 2015-08-05 17:04:01 -0300 |
commit | 57f0f512b273f60d52568b8c6b77e17f5636edc0 (patch) | |
tree | 5e910f0e82173f4ef4f51111366a3f1299037a7b /arch/blackfin/mach-bf561/atomic.S |
Initial import
Diffstat (limited to 'arch/blackfin/mach-bf561/atomic.S')
-rw-r--r-- | arch/blackfin/mach-bf561/atomic.S | 926 |
1 files changed, 926 insertions, 0 deletions
diff --git a/arch/blackfin/mach-bf561/atomic.S b/arch/blackfin/mach-bf561/atomic.S new file mode 100644 index 000000000..2a08df8e8 --- /dev/null +++ b/arch/blackfin/mach-bf561/atomic.S @@ -0,0 +1,926 @@ +/* + * Copyright 2007-2008 Analog Devices Inc. + * Philippe Gerum <rpm@xenomai.org> + * + * Licensed under the GPL-2 or later. + */ + +#include <linux/linkage.h> +#include <asm/blackfin.h> +#include <asm/cache.h> +#include <asm/asm-offsets.h> +#include <asm/rwlock.h> +#include <asm/cplb.h> + +.text + +.macro coreslot_loadaddr reg:req + \reg\().l = _corelock; + \reg\().h = _corelock; +.endm + +.macro safe_testset addr:req, scratch:req +#if ANOMALY_05000477 + cli \scratch; + testset (\addr); + sti \scratch; +#else + testset (\addr); +#endif +.endm + +/* + * r0 = address of atomic data to flush and invalidate (32bit). + * + * Clear interrupts and return the old mask. + * We assume that no atomic data can span cachelines. + * + * Clobbers: r2:0, p0 + */ +ENTRY(_get_core_lock) + r1 = -L1_CACHE_BYTES; + r1 = r0 & r1; + cli r0; + coreslot_loadaddr p0; +.Lretry_corelock: + safe_testset p0, r2; + if cc jump .Ldone_corelock; + SSYNC(r2); + jump .Lretry_corelock +.Ldone_corelock: + p0 = r1; + /* flush core internal write buffer before invalidate dcache */ + CSYNC(r2); + flushinv[p0]; + SSYNC(r2); + rts; +ENDPROC(_get_core_lock) + +/* + * r0 = address of atomic data in uncacheable memory region (32bit). + * + * Clear interrupts and return the old mask. + * + * Clobbers: r0, p0 + */ +ENTRY(_get_core_lock_noflush) + cli r0; + coreslot_loadaddr p0; +.Lretry_corelock_noflush: + safe_testset p0, r2; + if cc jump .Ldone_corelock_noflush; + SSYNC(r2); + jump .Lretry_corelock_noflush +.Ldone_corelock_noflush: + /* + * SMP kgdb runs into dead loop without NOP here, when one core + * single steps over get_core_lock_noflush and the other executes + * get_core_lock as a slave node. + */ + nop; + CSYNC(r2); + rts; +ENDPROC(_get_core_lock_noflush) + +/* + * r0 = interrupt mask to restore. + * r1 = address of atomic data to flush and invalidate (32bit). + * + * Interrupts are masked on entry (see _get_core_lock). + * Clobbers: r2:0, p0 + */ +ENTRY(_put_core_lock) + /* Write-through cache assumed, so no flush needed here. */ + coreslot_loadaddr p0; + r1 = 0; + [p0] = r1; + SSYNC(r2); + sti r0; + rts; +ENDPROC(_put_core_lock) + +#ifdef __ARCH_SYNC_CORE_DCACHE + +ENTRY(___raw_smp_mark_barrier_asm) + [--sp] = rets; + [--sp] = ( r7:5 ); + [--sp] = r0; + [--sp] = p1; + [--sp] = p0; + call _get_core_lock_noflush; + + /* + * Calculate current core mask + */ + GET_CPUID(p1, r7); + r6 = 1; + r6 <<= r7; + + /* + * Set bit of other cores in barrier mask. Don't change current core bit. + */ + p1.l = _barrier_mask; + p1.h = _barrier_mask; + r7 = [p1]; + r5 = r7 & r6; + r7 = ~r6; + cc = r5 == 0; + if cc jump 1f; + r7 = r7 | r6; +1: + [p1] = r7; + SSYNC(r2); + + call _put_core_lock; + p0 = [sp++]; + p1 = [sp++]; + r0 = [sp++]; + ( r7:5 ) = [sp++]; + rets = [sp++]; + rts; +ENDPROC(___raw_smp_mark_barrier_asm) + +ENTRY(___raw_smp_check_barrier_asm) + [--sp] = rets; + [--sp] = ( r7:5 ); + [--sp] = r0; + [--sp] = p1; + [--sp] = p0; + call _get_core_lock_noflush; + + /* + * Calculate current core mask + */ + GET_CPUID(p1, r7); + r6 = 1; + r6 <<= r7; + + /* + * Clear current core bit in barrier mask if it is set. + */ + p1.l = _barrier_mask; + p1.h = _barrier_mask; + r7 = [p1]; + r5 = r7 & r6; + cc = r5 == 0; + if cc jump 1f; + r6 = ~r6; + r7 = r7 & r6; + [p1] = r7; + SSYNC(r2); + + call _put_core_lock; + + /* + * Invalidate the entire D-cache of current core. + */ + sp += -12; + call _resync_core_dcache + sp += 12; + jump 2f; +1: + call _put_core_lock; +2: + p0 = [sp++]; + p1 = [sp++]; + r0 = [sp++]; + ( r7:5 ) = [sp++]; + rets = [sp++]; + rts; +ENDPROC(___raw_smp_check_barrier_asm) + +/* + * r0 = irqflags + * r1 = address of atomic data + * + * Clobbers: r2:0, p1:0 + */ +_start_lock_coherent: + + [--sp] = rets; + [--sp] = ( r7:6 ); + r7 = r0; + p1 = r1; + + /* + * Determine whether the atomic data was previously + * owned by another CPU (=r6). + */ + GET_CPUID(p0, r2); + r1 = 1; + r1 <<= r2; + r2 = ~r1; + + r1 = [p1]; + r1 >>= 28; /* CPU fingerprints are stored in the high nibble. */ + r6 = r1 & r2; + r1 = [p1]; + r1 <<= 4; + r1 >>= 4; + [p1] = r1; + + /* + * Release the core lock now, but keep IRQs disabled while we are + * performing the remaining housekeeping chores for the current CPU. + */ + coreslot_loadaddr p0; + r1 = 0; + [p0] = r1; + + /* + * If another CPU has owned the same atomic section before us, + * then our D-cached copy of the shared data protected by the + * current spin/write_lock may be obsolete. + */ + cc = r6 == 0; + if cc jump .Lcache_synced + + /* + * Invalidate the entire D-cache of the current core. + */ + sp += -12; + call _resync_core_dcache + sp += 12; + +.Lcache_synced: + SSYNC(r2); + sti r7; + ( r7:6 ) = [sp++]; + rets = [sp++]; + rts + +/* + * r0 = irqflags + * r1 = address of atomic data + * + * Clobbers: r2:0, p1:0 + */ +_end_lock_coherent: + + p1 = r1; + GET_CPUID(p0, r2); + r2 += 28; + r1 = 1; + r1 <<= r2; + r2 = [p1]; + r2 = r1 | r2; + [p1] = r2; + r1 = p1; + jump _put_core_lock; + +#endif /* __ARCH_SYNC_CORE_DCACHE */ + +/* + * r0 = &spinlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_spin_is_locked_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r3 = [p1]; + cc = bittst( r3, 0 ); + r3 = cc; + r1 = p1; + call _put_core_lock; + rets = [sp++]; + r0 = r3; + rts; +ENDPROC(___raw_spin_is_locked_asm) + +/* + * r0 = &spinlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_spin_lock_asm) + p1 = r0; + [--sp] = rets; +.Lretry_spinlock: + call _get_core_lock; + r1 = p1; + r2 = [p1]; + cc = bittst( r2, 0 ); + if cc jump .Lbusy_spinlock +#ifdef __ARCH_SYNC_CORE_DCACHE + r3 = p1; + bitset ( r2, 0 ); /* Raise the lock bit. */ + [p1] = r2; + call _start_lock_coherent +#else + r2 = 1; + [p1] = r2; + call _put_core_lock; +#endif + rets = [sp++]; + rts; + +.Lbusy_spinlock: + /* We don't touch the atomic area if busy, so that flush + will behave like nop in _put_core_lock. */ + call _put_core_lock; + SSYNC(r2); + r0 = p1; + jump .Lretry_spinlock +ENDPROC(___raw_spin_lock_asm) + +/* + * r0 = &spinlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_spin_trylock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r1 = p1; + r3 = [p1]; + cc = bittst( r3, 0 ); + if cc jump .Lfailed_trylock +#ifdef __ARCH_SYNC_CORE_DCACHE + bitset ( r3, 0 ); /* Raise the lock bit. */ + [p1] = r3; + call _start_lock_coherent +#else + r2 = 1; + [p1] = r2; + call _put_core_lock; +#endif + r0 = 1; + rets = [sp++]; + rts; +.Lfailed_trylock: + call _put_core_lock; + r0 = 0; + rets = [sp++]; + rts; +ENDPROC(___raw_spin_trylock_asm) + +/* + * r0 = &spinlock->lock + * + * Clobbers: r2:0, p1:0 + */ +ENTRY(___raw_spin_unlock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r2 = [p1]; + bitclr ( r2, 0 ); + [p1] = r2; + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _end_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + rts; +ENDPROC(___raw_spin_unlock_asm) + +/* + * r0 = &rwlock->lock + * + * Clobbers: r2:0, p1:0 + */ +ENTRY(___raw_read_lock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; +.Lrdlock_try: + r1 = [p1]; + r1 += -1; + [p1] = r1; + cc = r1 < 0; + if cc jump .Lrdlock_failed + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _start_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + rts; + +.Lrdlock_failed: + r1 += 1; + [p1] = r1; +.Lrdlock_wait: + r1 = p1; + call _put_core_lock; + SSYNC(r2); + r0 = p1; + call _get_core_lock; + r1 = [p1]; + cc = r1 < 2; + if cc jump .Lrdlock_wait; + jump .Lrdlock_try +ENDPROC(___raw_read_lock_asm) + +/* + * r0 = &rwlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_read_trylock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r1 = [p1]; + cc = r1 <= 0; + if cc jump .Lfailed_tryrdlock; + r1 += -1; + [p1] = r1; + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _start_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + r0 = 1; + rts; +.Lfailed_tryrdlock: + r1 = p1; + call _put_core_lock; + rets = [sp++]; + r0 = 0; + rts; +ENDPROC(___raw_read_trylock_asm) + +/* + * r0 = &rwlock->lock + * + * Note: Processing controlled by a reader lock should not have + * any side-effect on cache issues with the other core, so we + * just release the core lock and exit (no _end_lock_coherent). + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_read_unlock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r1 = [p1]; + r1 += 1; + [p1] = r1; + r1 = p1; + call _put_core_lock; + rets = [sp++]; + rts; +ENDPROC(___raw_read_unlock_asm) + +/* + * r0 = &rwlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_write_lock_asm) + p1 = r0; + r3.l = lo(RW_LOCK_BIAS); + r3.h = hi(RW_LOCK_BIAS); + [--sp] = rets; + call _get_core_lock; +.Lwrlock_try: + r1 = [p1]; + r1 = r1 - r3; +#ifdef __ARCH_SYNC_CORE_DCACHE + r2 = r1; + r2 <<= 4; + r2 >>= 4; + cc = r2 == 0; +#else + cc = r1 == 0; +#endif + if !cc jump .Lwrlock_wait + [p1] = r1; + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _start_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + rts; + +.Lwrlock_wait: + r1 = p1; + call _put_core_lock; + SSYNC(r2); + r0 = p1; + call _get_core_lock; + r1 = [p1]; +#ifdef __ARCH_SYNC_CORE_DCACHE + r1 <<= 4; + r1 >>= 4; +#endif + cc = r1 == r3; + if !cc jump .Lwrlock_wait; + jump .Lwrlock_try +ENDPROC(___raw_write_lock_asm) + +/* + * r0 = &rwlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_write_trylock_asm) + p1 = r0; + [--sp] = rets; + call _get_core_lock; + r1 = [p1]; + r2.l = lo(RW_LOCK_BIAS); + r2.h = hi(RW_LOCK_BIAS); + cc = r1 == r2; + if !cc jump .Lfailed_trywrlock; +#ifdef __ARCH_SYNC_CORE_DCACHE + r1 >>= 28; + r1 <<= 28; +#else + r1 = 0; +#endif + [p1] = r1; + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _start_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + r0 = 1; + rts; + +.Lfailed_trywrlock: + r1 = p1; + call _put_core_lock; + rets = [sp++]; + r0 = 0; + rts; +ENDPROC(___raw_write_trylock_asm) + +/* + * r0 = &rwlock->lock + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_write_unlock_asm) + p1 = r0; + r3.l = lo(RW_LOCK_BIAS); + r3.h = hi(RW_LOCK_BIAS); + [--sp] = rets; + call _get_core_lock; + r1 = [p1]; + r1 = r1 + r3; + [p1] = r1; + r1 = p1; +#ifdef __ARCH_SYNC_CORE_DCACHE + call _end_lock_coherent +#else + call _put_core_lock; +#endif + rets = [sp++]; + rts; +ENDPROC(___raw_write_unlock_asm) + +/* + * r0 = ptr + * r1 = value + * + * Add a signed value to a 32bit word and return the new value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_atomic_update_asm) + p1 = r0; + r3 = r1; + [--sp] = rets; + call _get_core_lock; + r2 = [p1]; + r3 = r3 + r2; + [p1] = r3; + r1 = p1; + call _put_core_lock; + r0 = r3; + rets = [sp++]; + rts; +ENDPROC(___raw_atomic_update_asm) + +/* + * r0 = ptr + * r1 = mask + * + * Clear the mask bits from a 32bit word and return the old 32bit value + * atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_atomic_clear_asm) + p1 = r0; + r3 = ~r1; + [--sp] = rets; + call _get_core_lock; + r2 = [p1]; + r3 = r2 & r3; + [p1] = r3; + r3 = r2; + r1 = p1; + call _put_core_lock; + r0 = r3; + rets = [sp++]; + rts; +ENDPROC(___raw_atomic_clear_asm) + +/* + * r0 = ptr + * r1 = mask + * + * Set the mask bits into a 32bit word and return the old 32bit value + * atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_atomic_set_asm) + p1 = r0; + r3 = r1; + [--sp] = rets; + call _get_core_lock; + r2 = [p1]; + r3 = r2 | r3; + [p1] = r3; + r3 = r2; + r1 = p1; + call _put_core_lock; + r0 = r3; + rets = [sp++]; + rts; +ENDPROC(___raw_atomic_set_asm) + +/* + * r0 = ptr + * r1 = mask + * + * XOR the mask bits with a 32bit word and return the old 32bit value + * atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_atomic_xor_asm) + p1 = r0; + r3 = r1; + [--sp] = rets; + call _get_core_lock; + r2 = [p1]; + r3 = r2 ^ r3; + [p1] = r3; + r3 = r2; + r1 = p1; + call _put_core_lock; + r0 = r3; + rets = [sp++]; + rts; +ENDPROC(___raw_atomic_xor_asm) + +/* + * r0 = ptr + * r1 = mask + * + * Perform a logical AND between the mask bits and a 32bit word, and + * return the masked value. We need this on this architecture in + * order to invalidate the local cache before testing. + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_atomic_test_asm) + p1 = r0; + r3 = r1; + r1 = -L1_CACHE_BYTES; + r1 = r0 & r1; + p0 = r1; + /* flush core internal write buffer before invalidate dcache */ + CSYNC(r2); + flushinv[p0]; + SSYNC(r2); + r0 = [p1]; + r0 = r0 & r3; + rts; +ENDPROC(___raw_atomic_test_asm) + +/* + * r0 = ptr + * r1 = value + * + * Swap *ptr with value and return the old 32bit value atomically. + * Clobbers: r3:0, p1:0 + */ +#define __do_xchg(src, dst) \ + p1 = r0; \ + r3 = r1; \ + [--sp] = rets; \ + call _get_core_lock; \ + r2 = src; \ + dst = r3; \ + r3 = r2; \ + r1 = p1; \ + call _put_core_lock; \ + r0 = r3; \ + rets = [sp++]; \ + rts; + +ENTRY(___raw_xchg_1_asm) + __do_xchg(b[p1] (z), b[p1]) +ENDPROC(___raw_xchg_1_asm) + +ENTRY(___raw_xchg_2_asm) + __do_xchg(w[p1] (z), w[p1]) +ENDPROC(___raw_xchg_2_asm) + +ENTRY(___raw_xchg_4_asm) + __do_xchg([p1], [p1]) +ENDPROC(___raw_xchg_4_asm) + +/* + * r0 = ptr + * r1 = new + * r2 = old + * + * Swap *ptr with new if *ptr == old and return the previous *ptr + * value atomically. + * + * Clobbers: r3:0, p1:0 + */ +#define __do_cmpxchg(src, dst) \ + [--sp] = rets; \ + [--sp] = r4; \ + p1 = r0; \ + r3 = r1; \ + r4 = r2; \ + call _get_core_lock; \ + r2 = src; \ + cc = r2 == r4; \ + if !cc jump 1f; \ + dst = r3; \ + 1: r3 = r2; \ + r1 = p1; \ + call _put_core_lock; \ + r0 = r3; \ + r4 = [sp++]; \ + rets = [sp++]; \ + rts; + +ENTRY(___raw_cmpxchg_1_asm) + __do_cmpxchg(b[p1] (z), b[p1]) +ENDPROC(___raw_cmpxchg_1_asm) + +ENTRY(___raw_cmpxchg_2_asm) + __do_cmpxchg(w[p1] (z), w[p1]) +ENDPROC(___raw_cmpxchg_2_asm) + +ENTRY(___raw_cmpxchg_4_asm) + __do_cmpxchg([p1], [p1]) +ENDPROC(___raw_cmpxchg_4_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Set a bit in a 32bit word and return the old 32bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_set_asm) + r2 = r1; + r1 = 1; + r1 <<= r2; + jump ___raw_atomic_set_asm +ENDPROC(___raw_bit_set_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Clear a bit in a 32bit word and return the old 32bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_clear_asm) + r2 = r1; + r1 = 1; + r1 <<= r2; + jump ___raw_atomic_clear_asm +ENDPROC(___raw_bit_clear_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Toggle a bit in a 32bit word and return the old 32bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_toggle_asm) + r2 = r1; + r1 = 1; + r1 <<= r2; + jump ___raw_atomic_xor_asm +ENDPROC(___raw_bit_toggle_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Test-and-set a bit in a 32bit word and return the old bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_test_set_asm) + [--sp] = rets; + [--sp] = r1; + call ___raw_bit_set_asm + r1 = [sp++]; + r2 = 1; + r2 <<= r1; + r0 = r0 & r2; + cc = r0 == 0; + if cc jump 1f + r0 = 1; +1: + rets = [sp++]; + rts; +ENDPROC(___raw_bit_test_set_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Test-and-clear a bit in a 32bit word and return the old bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_test_clear_asm) + [--sp] = rets; + [--sp] = r1; + call ___raw_bit_clear_asm + r1 = [sp++]; + r2 = 1; + r2 <<= r1; + r0 = r0 & r2; + cc = r0 == 0; + if cc jump 1f + r0 = 1; +1: + rets = [sp++]; + rts; +ENDPROC(___raw_bit_test_clear_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Test-and-toggle a bit in a 32bit word, + * and return the old bit value atomically. + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_test_toggle_asm) + [--sp] = rets; + [--sp] = r1; + call ___raw_bit_toggle_asm + r1 = [sp++]; + r2 = 1; + r2 <<= r1; + r0 = r0 & r2; + cc = r0 == 0; + if cc jump 1f + r0 = 1; +1: + rets = [sp++]; + rts; +ENDPROC(___raw_bit_test_toggle_asm) + +/* + * r0 = ptr + * r1 = bitnr + * + * Test a bit in a 32bit word and return its value. + * We need this on this architecture in order to invalidate + * the local cache before testing. + * + * Clobbers: r3:0, p1:0 + */ +ENTRY(___raw_bit_test_asm) + r2 = r1; + r1 = 1; + r1 <<= r2; + jump ___raw_atomic_test_asm +ENDPROC(___raw_bit_test_asm) + +/* + * r0 = ptr + * + * Fetch and return an uncached 32bit value. + * + * Clobbers: r2:0, p1:0 + */ +ENTRY(___raw_uncached_fetch_asm) + p1 = r0; + r1 = -L1_CACHE_BYTES; + r1 = r0 & r1; + p0 = r1; + /* flush core internal write buffer before invalidate dcache */ + CSYNC(r2); + flushinv[p0]; + SSYNC(r2); + r0 = [p1]; + rts; +ENDPROC(___raw_uncached_fetch_asm) |